DD149447A1 - ARRANGEMENT FOR DIGITAL BRIGHTNESS CONTROL OF LAMPS - Google Patents

Abstract

In an arrangement for digital brightness control of lamps, the technical-oekonomische effort should be reduced. For this reason, a purely digital and controlled by a selectable program control circuit arrangement for driving thyristors is to be created by simple means. According to the invention, a logic stage is provided for each drive channel associated with a network synchronization stage, a pulse generator and a power control stage. The logic stage contains at least one programmable counter and a bistable flip-flop and generates a network-synchronous pulse train whose duty cycle is dependent on the selectable divisor of the programmable counter. The programmable counter and the pulse generator are preferably components of a digital computer system.

Description

Title of the invention: Arrangement for the digital brightness control of lamps Field of application of the invention;

The invention relates to an arrangement for digital continuous brightness control of lamps, in particular for controlling the lighting of planetariums, comprising a single- or multi-phase Netzsynchronisationsetufe for generating network sync pulses and one or more control channels, each having a Leistungseteuerstufe with transistors or thyristors for the control of a respective lamp or lamp group in a brightness rating meter. In addition, lamps or groups of lerapen of different voltage, type and design can be controlled independently of one another in terms of brightness ". The invention is used in planetariums as well as for effect lighting, for example in the cinema and theater scene.

Characteristic of the known technical solutions; It is known from the circuit practice to generate by a Graetz- or full-wave rectification via an optocoupler with subsequent trigger 100 Hz pulses and to give an input of an integrator. A rectangular pulse sequence or (several switchable) are applied to a second input of the integrator

Rectangular rinse sequence appears at the output of the integrator

as a sawtooth pulse sequence which is reset synchronously via the 100-Hz · pulse

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Оіезе sawtooth pulse train is connected to the first input of a! Comparator «At the second input of the comparator is a DC voltage, which is obtained either at a DC voltage source or a DA converter. By comparison Sägezahnpulsfolge - DC voltage is at the output of the comparator, a pulse length modulated control signal for thyristors or triacs available

 When using DC voltage sources, relatively accurate or constant DC voltages must be provided. Although the use of OA converters is advantageous for program control, in particular by computer systems, the technical-economic complexity is thereby increased.

Similarly, from the circuit practice is known. Transistors with the analog signal from OA-VVandler, which in turn require a relatively high cost to control, in order to control the lamps. In addition to the high cost, this results in the disadvantage of the high power conversion when transistors are operated in the active area. Also known are (Tesla catalogs) special circuits with analog input for driving thyristors and triacs Olese circuits are digitally controlled by the analog input only by means of DA converter stages, whereby the technical and economic effort is again relatively high.

In addition, it is known (for example, "Guide to electronic control and regulation technology", Fransis-Verlag, Munich), to use thyristors and triacs to trigger unijunction transistors in circuit arrangements with a digital control input.

Via a transformer (or series resistor) a pulsating DC voltage is obtained via a full-wave rectification which charges a capacitor via series resistors until the breakdown voltage of the UOT is reached. The capacitor is discharged via the UOT, the current flows into the gate of a triac or into the primary winding a pulse transformer, if thyristors are used in anti-parallel connection ·

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Above a part of the series resistor is the collector-emitter path of a bipolar transistor · By a pulse at the base bipolar Transie gate prevents this charging the capacitor and thus the ignition of the triacs or thyristors · In these circuit arrangements, however, the thyristors are not expensive Digitization via computer controllable "Aue the same reference is known, for example," thyristors and triacs diacs with analog input signal to drive · Such circuits are, as already mentioned several times, not digitally controlled without expensive OA converter stages · Oa the thyristors via a selectable program control digitally controlled it is necessary, it would be necessary to omit the expensive DA conversion to provide a digital drive circuit ·

Aim of the invention;

The aim of the invention is to reduce the technical and economic effort ·

Explanation of the essence of the invention;

The invention is therefore based on the object with the simplest possible means to create a purely digital and controlled by a selectable program control circuitry for driving thyristors.

This object is in an arrangement for digital

Brightness control of lamps, in particular for controlling the lighting of planetariums, comprising a single- or multi-phase network synchronization stage for generating network synchronization pulses and one or more control channels, each having a power control stage with transistors, triacs or thyristors for the control of each lamp or group of lamps in a brightness control grid, According to the invention solved in that a pulse generator whose Irapulsfolgefrequenz of the

Bit number of brightness control grid subdivided

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Frequency of the network sync pulses corresponds, and for each control channel a programmable counter and via the network synchronization stage with a first input of each Logigstufe in connection and that each control channel of the output of the respective power control stage associated programmable counter with a two-th input of this power control stage Ee is advantageous, wean in each control channel the Logigstufe contains a bistable multivibrator whose first input to the output of the network synchronization stage, whose second input to the output of the programmable counter of the respective control channel and whose output is decoupled with the input of the Power control stage of the relevant control channel are connected, and when the pulse generator is connected via a controlled by the output of the bistable multivibrator gate to the input of the programmable counter · out It is also advantageous if both the pulse generator and the programmable counter are components of a digital computer system.

The control of the thyristors or triacs for the lamps or groups of lamps takes place in a purely digital way without complex DA converter systems. The circuit arrangement contains a network synchronization stage, a pulse generator and for each control channel a logic stage and a power control stage of known type · Thus, the circuitry complexity is minimal · A digital program control is possible if the programmable counter and possibly also the pulse generator parts of a computer system · The course of Brightness control of the lamp systems can thus be controlled in time, in the direction and in the speed by a program control "which also complicated control processes are possible with little user-technical effort.

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But even without computer control the brightness control is programmable by the circuit arrangement according to the invention in a simple manner in preset speeds · The brightness control can also be interrupted at any point and vice versa. The heart of the circuit arrangement according to the invention is the logic stage and its connection to the pulse generator, the network synchronization stage and the power control stage for each control channel. The logic stage generates a network-synchronous pulse sequence for the power control stage whose duty cycle changes in real time with the divider ratio of the programmable counter.

Working Example;

The invention will be explained in more detail below with reference to a draWei in the drawing embodiment:

Show it :

Fig. 1: Block diagram of the arrangement according to the invention for brightness control of one lamp in three control channels

FIG. 2: basic circuit for generating the drive

pulses for the power control stage of a control channel

FIG. 1 shows the block diagram of the arrangement according to the invention for controlling the brightness of one lamp each in three control channels. A bus system 1 of a microcomputer not shown separately in the drawing generates a CTC channel 2 of the microcomputer a frequency f, which is applied to an input 3 of a network synchronization stage 5. At the input 4 of the network synchronization stage 5 is an AC voltage U,

ι ο

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The output 3 of the CTC channel 2 is connected to a respective CLK / TRG input of 3 CTC channels 6, 7, 8 of the microcomputer "which are in each case connected to the bus system 1. The output of the network synchronization stage 5 is coupled to each a first input of three logic stages 9, 10, 11 · The output of the CTC channel 6 is guided in the first control channel for a lamp 12 to a second input of the logic stage 9 whose output is connected via a power control stage 13 to the lamp 12 In the same way, the CTC channel 7, the logic stage 10 and a power control stage 14 for a lamp 15 in the second drive channel and the CTC stage 8, the logic stage 11 and a power control stage for a lamp 17 in the third drive channel are connected together. Oeweils a terminal of the lamps 12, 15, 17 is located at an operating voltage U _ß . FIG. 2 shows the basic circuit arrangement of the invention for providing the drive pulses for one of the power control stages in a control channel (first control channel of FIG. 1).

The bus system 1 of the microcomputer is connected to the CTC channels 2 and 6 in connection. The outside of the CTC channel 2 is connected to the input 3 of the network synchronization stage 5 via a gate 20 whose second input is at a voltage U ₁ via a gate 21 to the CLK / TRG input of the CTC channel 6 out · The output of the CTC channel let via a gate 22 connected to a first input of a two-gate 23, 24 bistable flip-flop whose second input to the Output of the network synchronization stage 5 is coupled and whose output is guided both to a control input of the gate circuit 21 as well as via a resistor 25 to the base of a transistor 26 is in communication. From the transistor 26, the emitter to ground and the collector via a resistor 27 to a voltage U _{2 are} connected · At the same time, the collector of the transistor 26 as output A of the logic stage 9, as shown in Fig. 1, connected to the input of the power control stage 13 ·

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In the network synchronization stage 5, a pulse train of 100 Hz is generated at the zero crossing of the rectified AC voltage U. For an 8-bit brightness control grid of the lamps 12, 15, 17, the CTC channel 2 controlled by the bus system 1 becomes the very constant frequency f of

2 × 100 Hz - 25.6 kHz, which is present at the input 3 of the network synchronization stage 5. In the network synchronization stage 5, this frequency f is generated synchronously with the frequency f with the pulse sequence obtained from the rectified AC voltage U. The synchronization can be carried out with take a not shown in the drawing D-flip-flop. In the first drive channel for the lamp 12, the pulse train of the frequency f amplified in the gate 20 passes through the gate circuit 21 to the CLK / TRG input of the programmable countdown counter CTC channel 6 of the microcomputer · The CTC channel 6 is programmable via the Bus System 1 According to the first pulse appearing at the output of the CTC channel 6, after power amplification in the gate 22, the bistable one

Tilting of the gates 23, 24, the same time

Gate 21 is locked. With the next occurring synchronized 100 Hz pulse of the network synchronization stage 5, this bistable flip-flop at the gate 23 is tilted back and thus the gate circuit 21 is unlocked · In the next half cycle of the AC voltage U, this process is repeated · At the collector of the transistor 26 arises in the amplitude of the voltage U ₂ dependent network-synchronous pulse train whose duty cycle with the programmable divider ratio η echteaitmäßig changes · This is an 8-bit phase angle control for thyristors or triacs possible · the Kollektorausgangsslgnal of the transistor 26 is applied to the input of the power control stage 13 · passing the power control steps 13 of transistor actuators, the pulses at the output A switch the transistor actuator of the power control stage 13 in the first control channel constantly between the blocking and saturation range back and forth ·

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As a result of the inertia of the lamps, the optical output variable is the integral of the electrical input variable of the transistor actuator. As a result of the inertia of the human eye, only the brightness mean value is perceived.

Via the keypad 19, which is connected to the bus system 1 via the key interface 18, the CTC channels 6, 7, Q can be controlled or · Programmable · Preselection speeds can be realized in accordance with the number of bits of the brightness control grid · Non-linear dark / light or Light / dark control or switching functions can be implemented in a simple manner with the circuit arrangement according to the invention via a corresponding algorithm in the program control of the microcomputer. In the brightness control, a stop and direction change command can be given at any time.

If the lamps 12, 15, 17 are not continuously controlled, but merely switched, then the assigned CTC channels 6, 7, 8 are to be initialized with two fixed values of the divider ratio η, the one value corresponding to the state "dark" and For a different number of bits of the brightness control grid of the lamps, the CTC channel 2 must have a different frequency f, according to the subdivided by the respective desired number of bits of the brightness control grid Frequency of the network synchronizing pulses of the network synchronization stage 5, generate

The embodiment is particularly suitable for the control of a planetarium illumination, since the microcomputer from the planetarium control via the means mentioned in the embodiment simultaneously in a simple manner the stable frequency f and programmability of the duty cycle in acting as a counter CTC channels 6, 7, 8 guaranteed. The applicability of the He ··· However, the invention is universal and not limited to this embodiment and to the use in Planetcrien _л limited "

Claims (3)

Invention claim; 1. Arrangement for digital brightness control of lamps, in particular for controlling the lighting of planetariums, containing a single- or multi-phase network synchronization stage for generating network sync pulses and one or more control channels, each having a power control stage with transistors, triacs or thyristors for controlling one each A lamp or group of lamps in a brightness control grid, characterized in that a pulse generator whose pulse repetition frequency corresponds to the bit rate of the brightness control delay subdivided frequency of the network sync pulses, and for each control channel a programmable counter and a logic stage are provided that the output of the pulse generator with each programmable Zahler as well as via the Netzsynchonisationsetufe with in each case a first input of each logic stage is in communication and associated with each control channel of the output of the respective power control stage Programmable counter is connected to a second input of this Leietungssteuerstufe each upstream logic stage · 2 arrangement according to Pkt · 1, characterized in that in each control channel, the logic stage includes a bistable flip-flop, whose first input to the output of the Netzsynchronisationsstufe, whose second input to the output of the programmable counter of the respective control channel and whose output is decoupled with the input the power control stage of the relevant control channel are connected, and that the pulse generator is connected to the input of the programmable counter via a gate circuit controlled by the output of the bistable flip-flop. 3 · Arrangement according to item 1, characterized in that both the pulse generator and the programmable counter components of a digital computer system sin ^J 3566 For this Z / strings drawings